System and method for test to production support in a cloud platform environment

ABSTRACT

In accordance with an embodiment, described herein is a system and method for replicating a source service domain to a target service domain in a cloud computing platform environment. In accordance with an embodiment, the system comprises a cloud platform component provided as an installable software suite within the cloud environment, that supports provisioning of enterprise applications; a test to production (T2P) framework module that includes a plurality of T2P plugins and a PaaS plugin; and a user interface where an administrator or a user can invoke the plugins to replicate a source service domain to a target service domain. The system allows a user to manually customize move plans for service domain configurations based on the requirements of the target service domain, and recreate the configurations in the target service domain in accordance with the customized move plans.

CLAIM OF PRIORITY

This application claims the benefit of priority to U.S. ProvisionalApplication titled “SYSTEM AND METHOD FOR PROVIDING INTEGRATION AND TESTTO PRODUCTION SUPPORT IN A CLOUD PLATFORM ENVIRONMENT”, Application No.61/897,723, filed Oct. 30, 2013, which application is hereinincorporated by reference.

COPYRIGHT NOTICE

A portion of the disclosure of this patent document contains materialwhich is subject to copyright protection. The copyright owner has noobjection to the facsimile reproduction by anyone of the patent documentor the patent disclosure, as it appears in the Patent and TrademarkOffice patent file or records, but otherwise reserves all copyrightrights whatsoever.

FIELD OF INVENTION

Embodiments of the invention are generally related to cloud computing,and in particular to cross-environment replication of configurations andservices in a cloud platform.

BACKGROUND

The term “cloud computing” is generally used to describe a computingmodel which enables on-demand access to a shared pool of computingresources, such as computer networks, servers, software applications,and services, and which allows for rapid provisioning and release ofresources with minimal management effort or service providerinteraction.

A cloud computing environment (sometimes referred to as a cloudenvironment, or a cloud) can be implemented in a variety of differentways to best suit different requirements. Generally, a cloud computingmodel enables some of those responsibilities which previously may havebeen provided by an organization's own information technologydepartment, to instead be delivered as service layers within a cloudenvironment, for use by consumers (either within or external to theorganization, according to the cloud's public/private nature).

As an illustrative example, a cloud computing model can be implementedas Platform as a Service (PaaS), in which consumers can use softwareprogramming languages and development tools supported by a PaaS providerto develop, deploy, and otherwise control their own applications, whilethe PaaS provider manages or controls other aspects of the cloudenvironment (i.e., everything below the run-time execution environment).

In such an environment, it can be beneficial to test that the servicesof the environment are operating properly. For example, one or moreservice domains can be installed, configured, customized, and validatedin a source or test environment, prior to rolling out those servicedomains to a target or production environment.

However, replicating such a service domain, for example from a testenvironment to a production environment, typically requires replicatingthe configurations and services from the source service domain to thetarget service domain. Often, this requires considerable effort on thepart of an administrator, for example to reapply configuration changesmade in the original environment to the new environment. These are thegeneral areas that embodiments of the invention are intended to address.

SUMMARY

In accordance with an embodiment, described herein is a system andmethod for replicating a source service domain to a target servicedomain in a cloud computing platform environment. In accordance with anembodiment, the system comprises a cloud platform component provided asan installable software suite within the cloud environment, thatsupports provisioning of enterprise applications; a test to production(T2P) framework module that includes a plurality of T2P plugins and aPaaS plugin; and a user interface where an administrator or a user caninvoke the plugins to replicate a source service domain to a targetservice domain. The system allows a user to manually customize moveplans for service domain configurations based on the requirements of thetarget service domain, and recreate the configurations in the targetservice domain in accordance with the customized move plans.

BRIEF DESCRIPTION OF THE FIGURES

FIG. 1 illustrates an example of a cloud computing environment, inaccordance with an embodiment.

FIG. 2 illustrates a PaaS platform component, including anadministration server and a service domain, in accordance with anembodiment.

FIG. 3 illustrates the use of service definition packages and servicemanagement engines with an administration server, in accordance with anembodiment

FIG. 4 illustrates the interaction between an administration server anda virtualization manager, in accordance with an embodiment

FIG. 5 illustrates a multiple tenant service domain, in accordance withan embodiment.

FIG. 6 illustrates a cloud account manager, in accordance with anembodiment

FIG. 7 illustrates the use of a service definition package, inaccordance with an embodiment.

FIG. 8 illustrates the use of a service management engine, in accordancewith an embodiment.

FIG. 9 illustrates the use of an orchestration engine, in accordancewith an embodiment.

FIG. 10 illustrates the use of an elasticity manager, in accordance withan embodiment.

FIG. 11 illustrates a system for use in replicating a source servicedomain to a target service domain, in accordance with an embodiment.

FIG. 12 illustrates a system for use in migrating domain configurationsfrom a source service domain to a target service domain, in accordancewith an embodiment.

FIG. 13 further illustrates a system for use in migrating domainconfigurations from a source service domain to a target service domain,in accordance with an embodiment.

FIG. 14 illustrates a system for use in editing move plans, inaccordance with an embodiment.

FIG. 15 further illustrates a system for use in migrating domainconfigurations from a source service domain to a target service domain,in accordance with an embodiment.

FIG. 16 illustrates setting up a target service domain, in accordancewith an embodiment.

FIG. 17 illustrates recreating domain configurations in a target servicedomain, in accordance with an embodiment.

FIG. 18 illustrates a method of replicating a source domain to a targetservice domain, in accordance with an embodiment.

FIG. 19 illustrates a system for use in exporting a service from asource service domain to a target service domain, in accordance with anembodiment.

FIG. 20 illustrates a system for creating a domain configuration archivefor use in exporting a service from a source service domain to a targetservice domain, in accordance with an embodiment.

FIG. 21 illustrates a system for use in importing a service to a targetservice domain, in accordance with an embodiment.

FIG. 22 illustrates a method of exporting a service from a source to atarget service domain, in accordance with an embodiment.

FIG. 23 illustrates a method of importing a service to a target servicedomain, in accordance with an embodiment.

FIG. 24 illustrates a high level overview of cloning a service within aPaaS platform, in accordance with an embodiment.

FIG. 25 illustrates a system for use in providing a clone service withina service domain, in accordance with an embodiment.

FIG. 26 illustrates creating a service backup within a service domain,in accordance with an embodiment.

FIG. 27 further illustrates a system for use in providing a cloneservice within a service domain, in accordance with an embodiment.

FIG. 28 further illustrates a system for use in providing a cloneservice within a service domain, in accordance with an embodiment.

FIG. 29 illustrates cloning a service to run on a differentvirtualization, in accordance with an embodiment

FIG. 30 illustrates cloning a service across service domains, inaccordance with an embodiment.

FIG. 31A is a sequence diagram that illustrates cloning a service withina service domain, in accordance with an embodiment.

FIG. 31B is a continuation of the sequence diagram from FIG. 31A, inaccordance with an embodiment.

FIG. 32 is a sequence diagram that illustrates cloning a service acrossservice domains, in accordance with an embodiment.

FIG. 33 illustrates a method for providing a clone service within aservice domain, in accordance with an embodiment.

FIG. 34 illustrates a method for providing a clone service acrossservice domains, in accordance with an embodiment.

DETAILED DESCRIPTION

In accordance with an embodiment, a cloud computing environment enablesresponsibilities which previously may have been provided by anorganization's own information technology department, to be delivered asservice layers within a cloud environment, for use by consumers that areeither internal (i.e., private) or external (i.e., public) to theorganization. Described herein are a variety of hardware and/or softwarecomponents and features, which can be used in delivering aninfrastructure, platform, and/or applications to support cloudcomputing.

FIG. 1 illustrates an example of a cloud computing environment, inaccordance with an embodiment. As shown in FIG. 1, a cloud computingenvironment (referred to herein in some embodiments as a cloudenvironment, or cloud) 10 can generally include a combination of one ormore Infrastructure as a Service (IaaS) 20, Platform as a Service (PaaS)60, and/or Software as a Service (SaaS) 70 layers, which can bedelivered as service layers within the cloud environment. The cloudenvironment can be implemented as a system that includes a computerhardware 15, such as one or more conventional general purpose orspecialized digital computers, computing devices, machines,microprocessors, memory and/or computer readable storage media.

In accordance with an embodiment, each of the IaaS, PaaS, and/or SaaSlayers can generally include a variety of components. For example, inaccordance with an embodiment, the IaaS layer can include a shareddatabase hardware (e.g., an Exadata machine), and/or shared applicationserver hardware (e.g., an Exalogic machine); while the PaaS layer caninclude one or more PaaS services, such as a database service,application server service, and/or WebCenter service; and the SaaS layercan include various SaaS services, such as enterprise applications(e.g., Oracle Fusion SaaS), and/or ISV or custom applications. The cloudenvironment can also include a shared enablement and managinginfrastructure 30, which provides enablement and management tools thatsupport the various service layers, for example, identity management,virtual assembly builder, system provisioning, tenant management, orother components.

In accordance with an embodiment, the cloud environment can include aPaaS platform component 100 (referred to herein in some embodiments as aPaaS platform, or CloudLogic), which enables the provisioning ofenterprise software applications within the environment. For example,the PaaS platform can be provided as an installable software suite thatprovides a self-service provisioning experience for enterpriseapplications such as Fusion Middleware (FMW).

As shown in FIG. 1, in accordance with an embodiment, the PaaS platformcan include one or more service definition package (SDP) 102, servicemanagement engine (SME) 104, virtual assembly (VA) 106, PaaSadministration server 108, service domain 110 including one or moreservice applications (apps) 112 for use by one or more cloud accounts ortenants 113, and/or elasticity manager 114 components.

The example shown in FIG. 1 is provided as an illustration of anexemplary cloud environment and PaaS platform. In accordance with otherembodiments, different and/or other types or arrangements of componentscan be included.

In accordance with an embodiment, the following terms are used herein.

PaaS Platform Component (PaaS Platform, Platform, CloudLogic): Inaccordance with an embodiment, a PaaS platform component is aninstallable software suite that provides a self-service provisioningexperience for enterprise applications, such as FMW or other enterpriseapplications.Site: In accordance with an embodiment, a site is the entity created andconfigured by the Platform Administrator from a PaaS platforminstallation, which tenants and Platform Administrators interact with toperform the various operations in the platform. In accordance with anembodiment, a site can be implemented as a WebLogic domain.Tenant: In accordance with an embodiment, a tenant (referred to hereinin some embodiments as an account) is an entity that is associated withusers that consume the platform as a service, and establishes anadministrative scope that administrators use to access PaaS services.For example, a tenant can be created for an organization, department, orgroup. Roles such as Tenant Administrator can be associated with atenant; and quotas can be assigned to a tenant. A tenant can create oneor more environments, and have one or more sub-tenants. Consumedresources, such as services with their virtual machines, databases, DNSentries, load balancer and other configurations, can be associated witha tenant.Sub-tenant: In accordance with an embodiment, a sub-tenant is an entitythat exists under a tenant. A sub-tenant has a quota assigned from theoverall tenant's quota. For example, a tenant can have one or moresub-tenants, and the Tenant Administrator can assign a quota from theoverall tenant quota to each sub-tenant. A sub-tenant can create one ormore environments.Service Definition Package: In accordance with an embodiment, a servicedefinition package (SDP) is a package that contains the informationnecessary for a particular type of service to be offered by the PaaSplatform. For example, each type of FMW service can provide its own SDP.An SDP can contain custom code that is installed into the cloudplatform, and a virtual assembly that contains the topology andconfiguration of a set of virtual appliances that will comprise arunning instance of the service, upon being deployed onto a set ofvirtual machines (VMs).Service Management Engine: In accordance with an embodiment, a servicemanagement engine (SME) provides a generic means to plug any servicetype into the system. For example, an SME takes care of theservice-specific provisioning, lifecycle, management, and monitoringsupport for a service type or provider type.Service Type: In accordance with an embodiment, a service type is arepresentation of software functionality that can be instantiated withinthe PaaS platform site for a tenant. A service type is created based onan SDP, with additional configuration information supplied by thePlatform Administrator. Some of this configuration information maysupply values that are specific to an installation of the PaaS platformproduct or the enterprise in which it is running; while someconfiguration information may reflect the Platform Administrator'schoices of options supported by the SDP. Multiple service types can becreated from a single SDP, by making different configuration choices.Environment: In accordance with an embodiment, an environment is acollection of services and their associated providers that are managedtogether as a group. An environment can be created for the purpose ofrunning an application or providing some higher level service.Environments provide the ability to operate on the collection ofservices as a whole, with operations such as start, stop, backup, anddestroy. An environment provides the functions of an association group,and a management group.Service: In accordance with an embodiment, a service is an instantiationof a service type. An environment can be associated with multipleservices; and within a particular tenant there can be one or moreenvironments with multiple services for a single service type.Typically, a service provides both a service administration interface,and an end-user interface. A service can be associated with identity,database, or other service features that are required by the service;and with a service runtime that runs on one or more VMs.Provider Type: In accordance with an embodiment, a provider type is aspecial form of service type that supports providers instead ofservices. Provider types are created by the Platform Administrator inthe same way as service types. As with service types, a provider type iscreated based on an SDP, with additional configuration informationsupplied by the Platform Administrator. Some of this configurationinformation may supply values that are specific to this installation ofthe PaaS platform product or the enterprise in which it is running;while some configuration information may reflect the PlatformAdministrator's choices of options supported by the SDP. Multipleprovider types can be created from a single SDP, by making differentconfiguration choices.Provider: In accordance with an embodiment, a provider is aspecialization of a service. Unlike services, which are created byexplicit action of a Tenant Administrator, providers are createdon-demand to satisfy the dependencies of services. A provider is aninstantiation of a provider type, and represents the use of the resourcemanaged by the provider type by a particular instance of a service type.Services can be associated with multiple providers. When creating aservice, an orchestration engine matches the requirements of a servicetype with the capabilities of the configured provider types, and thenrequests the service type to create an instance of a service, and theprovider types to create instances of the providers for use by thisinstance of the service. The orchestration engine then associates theservice with the providers.Association Resource: In accordance with an embodiment, an associationresource (sometimes referred to as a provider resource) enables aservice to keep track of configuration information for a particularassociation. For example, if a Java Service is associated with twodifferent database providers, it may need to create a connection poolfor each database. The association resource enables the Java Service tokeep track of which connection pool is associated with which database,so that, if the orchestration engine needs to change one of theassociations, the Java Service will know which connection pool tochange.Runtime: In accordance with an embodiment, a runtime is a representationof the installed and operational software that provides thefunctionality of a service or a provider. Runtimes are managed by thecustom code included in an SDP, in some instances using facilitiesprovided by the PaaS platform, such as its virtualization andprovisioning support. Runtimes can be layered, with each layer beingshared (multi-tenant), or not shared (dedicated). For example, with aJava Service, the runtime layers may include an application server, aJava virtual machine (JVM), a guest operating system (OS), and a hostoperating system. When unqualified, the expression “service runtime”generally refers to the top-most layer. For example, a multi-tenantservice runtime is a runtime that is shared by multiple services; whilea dedicated service runtime is a runtime that is not shared amongmultiple services.Service Resource Type: In accordance with an embodiment, a serviceresource type is a special form of service type that supports serviceresources instead of services. Service resource types are created by thePlatform Administrator in the same way as service types. As with servicetypes, a service resource type is created based on an SDP, withadditional configuration information supplied by the PlatformAdministrator. Multiple service resource types can be created from asingle SDP, by making different configuration choices.Service Resource: In accordance with an embodiment, a service resourceis a specialization of a service. Unlike services, which are created byexplicit action of a Tenant Administrator, and providers which arecreated on-demand to satisfy the dependencies of services, serviceresources are associated with services to satisfy the dependencies ofartifacts/applications deployed to services. A service resource can beassociated, or disassociated, with a service after the service has beencreated. A service resource dependency of a service is optional and maybe configured by the Platform or Tenant Administrator based on the needsof the artifacts/applications that would be deployed to the service. Forexample, a service may indicate support for multiple kinds of serviceresource dependencies; and the Platform or Tenant Administrator mayassociate multiple service resources for a dependency. A serviceresource is an instantiation of a service resource type, and representsthe use of the infrastructure managed by the service resource type, by aparticular instance of a service type. A Service can be associated withone or more service resources. The association of a service to a serviceresource can happen at any time in the lifecycle of the service, oncethe service and service resource have been created.Quota: In accordance with an embodiment, a quota provides a mechanism tolimit consumption of a resource, by establishing an upper bound on theresource usage. Examples of quota-controlled resources include CPU,disk, and the number of VMs in use. PaaS layer quotas can also besupported, for example the number of services that can be provisioned.Quotas can be assigned to tenants, and a Tenant Administrator canallocate their quota to projects or groups which they manage.Namespaces: In accordance with an embodiment, the PaaS platform can usea naming hierarchy, such as a Nimbula-style naming hierarchy andmultipart naming scheme. There can be reserved namespaces for SDPs,service-types, provider-types, service-resource-types,service-resources, environments, and services. Namespaces can be definedand reserved at the global level, and per tenant.Platform Administrator/System Administrator (Role): In accordance withan embodiment, a Platform or System Administrator is responsible forinstalling, configuring, managing, and maintaining the PaaS platforminfrastructure and environment, including the resources that are madeavailable to applications running in the environment. The Platform orSystem Administrator is also responsible for downloading and installingSDPs to support additional service types, setting up or configuringvirtualization technology for the platform to use, and installing andconfiguring providers.Cloud Account Administrator (Role): In accordance with an embodiment, aCloud Account Administrator is responsible for the provisioning of newservices, management of generic service properties such as their Qualityof Service (QoS) settings and their associations, and the locking andtermination of services. A Cloud Account Administrator can assignService Administrators for each service.Tenant Administrator (Role): In accordance with an embodiment, a TenantAdministrator is responsible for creating sub-tenants and assigningTenant Administrator to the sub-tenant groups, and for the provisioningof new services, management of generic service properties, and thelocking and termination of services. A Tenant Administrator can assignService Administrators for each service.Service Administrator (Role): In accordance with an embodiment, aService Administrator is responsible for administering and managing aspecific service after it has been provisioned. A Service Administratorinteracts with the service's administration interface to performadministration and management operations.Service Runtime Administrator (Role): In accordance with an embodiment,a Service Runtime Administrator is responsible for configuring andmanaging service runtimes.Application Deployer (Role): In accordance with an embodiment, anApplication Deployer deploys an application to the provisioned service,and is responsible for installing, configuring, and running theapplication. Once the application is running, it can be made availableto an End User.End User (Role): In accordance with an embodiment, an End User is theuser of the applications that are deployed to the service. The End Userinteracts with the user interface provided by the application running inthe service. If the service itself provides an interface for users toconsume the functionality that it exposes, then the End User can usethat service's interface.

FIG. 2 illustrates an administration server and a service domain, inaccordance with an embodiment. As shown in FIG. 2, in accordance with anembodiment, the PaaS platform (platform) comprises a PaaS administrationserver 108, which supports an administration console 120, cloud platformprovisioning/management logic 121, and virtual assembly builder (VAB)deployer 122, together with a virtual assembly or VAB repository 124.The VAB deployer can be provided by functionality, components, orproducts such as Oracle Virtual Assembly Builder (OVAB). The VABdeployer (e.g., OVAB Deployer) can then be used by the platform tomanage those VMs that will host the servicing applications.

In accordance with an embodiment, the PaaS administration server can beimplemented as a WebLogic (WLS) server application, together with, e.g.,Glassfish modules embedded therein to provide cloud platformfunctionality. A service domain, including a service app and serviceconsole 132, can be provided for housing enterprise applications, suchas FMW applications, that will ultimately service user requests. Inaccordance with an embodiment, the service domain components may beinstantiated multiple times as part of provisioning requests.

In accordance with an embodiment, provider server types that will beused by the PaaS administration server and the service domain, examplesof which include LDAP 126, database 127, and Web tier 128 orload-balancer 130 providers, can be provided in pools that are notprovisioned by the administration server, but are external servicesregistered with the cloud environment. In accordance with an embodiment,the PaaS platform can make use of a load-balancer provider to forwardall incoming, e.g., Web requests, that are directed to the services. Forexample, each service can be associated with a virtual host name thatwill be registered with the load-balancer provider during serviceprovisioning.

FIG. 3 illustrates the use of service definition packages and servicemanagement engines with an administration server, in accordance with anembodiment. As shown in FIG. 3, in accordance with an embodiment, newenterprise application service types (e.g., new FMW service types),which the administrator wishes to make available for use within the PaaSplatform, can be installed from an SDP. Each SDP contains custom codethat can be injected into the platform, for use in supporting, e.g.,elasticity and provisioning; together with a virtual assembly (e.g., anOVAB assembly) that contains the topology and configuration of a set ofvirtual appliances that will comprise a running instance of theenterprise application service, once the assembly is deployed onto a setof VMs.

FIG. 4 illustrates the interaction between an administration server anda virtualization manager, in accordance with an embodiment. As shown inFIG. 4, in accordance with an embodiment, a VM manager component 141(e.g., Oracle's OVM Manager) can be used by the PaaS platform to managethe pool 140 of VMs 142, 143, 144, which are then used in instantiatinga service assembly. When a request is made from a platform module toinstantiate an assembly, or a single appliance in the case of a scale-uprequest, the VAB deployer application (e.g., OVAB Deployer) can interactwith the VM manager to fulfill the request. By delegating theinfrastructure/virtualization responsibilities to the VM manager and VABdeployer in this manner, the platform can be abstracted from the targetdeployment platform.

FIG. 5 illustrates a multiple tenant service domain, in accordance withan embodiment. As shown in FIG. 5, in accordance with an embodiment, aservice domain can include multiple tenants 150, 151, 152, that areconfigurable using the service console. Multi-tenancy, likevirtualization, is a density optimization that allows the use of lessresources to support more clients and, similar to virtualization, shouldbe transparent to the applications themselves. Although multi-tenancyinvolves the use of shared resources, the sharing need not be part ofthe logical model of the applications—these models are instead referredto as using “multitenant” and “dedicated” resources. Alternatively,applications may share resources in a manner that is part of the logicalmodel of the applications; for example, two applications may purposelyaccess a shared database because they intend to operate on the samedata—these models are referred to as using “shared” and “unshared”resources.

In accordance with an embodiment, some service types may support bothdedicated and multitenant uses, based on their particular configuration.Other service types may support either only dedicated use, or onlymultitenant use. Service types that are able to support multiple tenantson the same runtime can provision their runtimes in a multitenantmanner, during the instantiation process, based on the configuration ofthe service type. A single instantiated service runtime that has beenmarked as multitenant-capable will be reused for a finite number ofadditional service provisioning requests, as determined by the servicetype and based on its configuration. Generally, it is left to theservice application to support a particular tenancy mode; serviceapplications that are not multitenant will only be able to support asingle account for each service instance. Once a service has beeninstantiated from its VM assembly, end users 146 can interact with thesystem and the instantiated services, in the same manner as they wouldinteract with an on-premise version of that service.

FIG. 6 illustrates a cloud account manager, in accordance with anembodiment. As shown in FIG. 6, in accordance with an embodiment, thePaaS platform can include a cloud platform administration service (CPAS)160, together with a cloud account manager 170 which supports functionssuch as account management, and provides a framework that other modules,such as the orchestration engine/SMEs 162, cloud elasticity manager(CEM, referred to herein in some embodiments as an elasticity manager)164, or identity management service 166), can use to accessaccount-specific data. A configuration management component 173 can usea configuration layer 180 to persist account specific configuration 183and other files 184 to an account store 182. An account managementmodule 174 provides the ability to manage accounts for a CPAS domain,which can be exposed through the use of a command-line, REST, or otheridentity management application program interface (API) 181.

In accordance with an embodiment, users can either be managed within anidentity store 186 managed by the PaaS platform, or alternatively can beprovided from an external, e.g., corporate LDAP, or other means of useridentification; and can access the cloud account manager through anadministration interface 172. Account and configuration data can also bestored on a file system or other means of storage that is accessiblefrom nodes of a CPAS cluster.

Service Definition Package (SDP)

FIG. 7 illustrates the use of a service definition package, inaccordance with an embodiment. As shown in FIG. 7, in accordance with anembodiment, each SDP 192, 196 can include a binary 193, 197; a metadata194, 198 (e.g., the SDP name, service type, version, vendor, orvirtualization support metadata such as indicating whether the SDPsupports OVAB, EC2, or Native); and one or more plugins 195, 199 thatenable the SDP to be used within a PaaS platform or cloud environment.

For example, in accordance with an exemplary embodiment, each SDP caninclude an assembly, reference, package, archive, or template, which canbe used to install a service on a particular virtualization provider(e.g., OVAB); an assembly bundled within the SDP or a reference to anassembly (e.g., an EC2-specific reference); a service management engine(SME) plugin for the service type, which enables platform functionalitysuch as elasticity metric gatherers, or alerts to be used with theservice; a plugin for use with a VAB deployer (e.g., OVAB Deployer)during its assembly rehydration process; and other dependency andconfiguration information, such as scalability limits or whether theservice is a multitenant or dedicated service.

In accordance with an embodiment, installing an SDP will install, e.g.,the OVAB assembly into the OVAB repository; appropriate SME plugins willbe registered with the cloud platform; and metric gatherers, alerts andactions will be installed in the PaaS platform. After a SystemAdministrator installs the SDP, a Cloud Account Administrator can thenuse a cloud account administration interface to request for a service ofthat type.

In accordance with an embodiment, when an SDP is installed into a PaaSplatform domain, it is consumed by an SDP Manager 190, which isresponsible for obtaining a list of SDPs available to be installed thelocal system, downloading an SDP if necessary, installing parts of theSDP into the right places, maintaining a list of those SDPs that havebeen installed, and, if necessary, uninstalling an SDP by uninstallingall of its parts from the places they were previously installed.

In accordance with an embodiment, the SDP manager can interface withother system components by installing an SME plugin to the CPAS, whichcan then take responsibility for replicating the SME plugin to otherCPAS instances in the cluster, installing the VAB assembly 202, 204 intothe VAB deployer, interfacing with other tools such as EnterpriseManager to provide a customized console interface for the service if theservice provides one, and installing configuration data for the serviceinto the CPAS. Subsequently, during realization 206 of a service, theservice 210 can be realized as an instance of those service typesdefined by the SDP and installed as assemblies in the VAB repository.

Service Management Engine (SME)

FIG. 8 illustrates the use of a service management engine, in accordancewith an embodiment. In accordance with an embodiment, a ServiceManagement Engine (SME) provides a generic means to plug any servicetype into the system. For example, an SME takes care of theservice-specific provisioning, lifecycle, management, and monitoringsupport for a service type or provider type. There can be differentclasses of SMEs; for example, provider SMEs can be provided to handledifferent providers. Service SMEs can be dynamically incorporated intothe platform domain by installing an appropriate SDP, which are thenregistered by the SDP manager. The set of registered service SMEs thenbecome the service types that are available to Cloud AccountAdministrators to create services.

In accordance with an embodiment, each service type supported in thePaaS platform domain maps to a specific service SME. A service SMEhandles all service-related activities, such as creation, monitoring,management, patching, upgrade, and deletion for that service. Inaccordance with an embodiment, the contract that is implemented by anSME is referred to as a Service Management Interface (SMI).

Referring to the example shown in FIG. 8, when OVAB is used as avirtualization provider, interaction with the OVAB Deployer can behandled by a virtualization API (e.g., an

OVAB client API). In accordance with an embodiment, the orchestrationprocess can then proceed as follows: a Cloud Account Administrator candiscover, e.g., SOA service types 220, 222 that are available in thePaaS platform domain, and initiate creation of an, e.g., SOA service.The orchestration engine iterates through the available service SMEs inthe system, and determines which service SMEs can handle this servicetype 224. In this example, the orchestration engine can discover anappropriate SOA SME to handle creation of the SOA service. Theorchestration engine can then call into the SME to get all providerdependencies for that SME 225. For example, the SME may return databaseand load-balancer provider dependencies. The orchestration engine canthen call a get-user or similar configurable properties function for theSME, and expose those properties in a user interface, so that the CloudAccount Administrator can edit the properties if desired. User-providedinputs can be supplied to the SME, for example to update an OVABdeployment plan. The orchestration engine then performs anypre-provisioning association between the SME and the provider SMEs uponwhich it depends. For example, the orchestration engine can performpre-provisioning association between the SOA SME and a database providerSME, which results in the creation of schema and tables required by theSOA service, in addition to populating the deployment plan with thedatabase provider configuration. When any pre-provisioning associationis complete, the orchestration engine can then call into the SME 226 toprovision the service.

At this point, the deployment plan is generally complete except fornetwork configurations. In accordance with an embodiment, the deploymentplan together with an assembly ID can be pushed, e.g., to the OVAB API,which takes care of filling the deployment plan with the remainingnetwork configurations. Then, the orchestration engine can call, e.g., aWeb service API of the OVAB Deployer, to provision the OVAB assembly.Once the assembly is provisioned, the virtual machine information can beretrieved and passed back to the SME, which in turn passes theinformation back to the orchestration engine. The orchestration enginecan then perform any post-provisioning association between the SME andthe provider SMEs on which it depends. For example, post-provisioningassociation between the SOA SME and a load-balancer provider SME mayresult in the creation of a virtual server to handle and route requestsfor this SOA service.

Orchestration Engine (OE)

FIG. 9 illustrates the use of an orchestration engine, in accordancewith an embodiment. In accordance with an embodiment, the orchestrationengine enables life-cycle management of the services in a PaaS platform.In particular, the orchestration engine coordinates the interactionsamong various components in the platform domain while creating ormanaging a service, enables the pluggability of SMEs for various servicetypes in the platform, aids in provisioning the service by selectingappropriate SMEs from among those available in the platform, and helpsin managing the configuration of providers such as DB Providers, IDMProviders, and LB Providers.

In accordance with an embodiment, the orchestration engine, as part ofcreating a service, ensures that dependencies of the service, such asits provider dependencies, are satisfied, by selecting appropriateproviders, and coordinating association between the providers andservice. The act of association can be performed during pre-provisioningand/or post provisioning-phases. The act of installing and configuringan SME can be performed by the SDP manager as part of registering apre-packaged service type or a customized service type. Theorchestration engine helps expose the deployment plan configuration,which can be configured by the Cloud Account Administrator, includingrecognizing phases and tasks that match the requirements of the platformfor its service creation action, and other life-cycle relatedactivities.

In accordance with an embodiment, the orchestration engine also acts asa gateway for service management, monitoring, scaling actions that couldbe initiated by other containers in the PaaS platform domain, or by anadministrator. For example, the elasticity engine, described in furtherdetail below, can communicate with the orchestration engine to manage,monitor, and scale services based on a service's QoS configuration. Theorchestration engine can also play a role in service maintenanceactions, such as patching and upgrade, which may require disassociatingor re-associating services in a phased manner.

In accordance with an embodiment, services created by a cloud accountadministrator are visible and accessible only to that particular cloudaccount (tenant), and are isolated from other cloud accounts in the PaaSplatform domain. Such isolation can be provided by the orchestrationengine with the help of a cloud account management module.

In accordance with an embodiment, SMEs can be registered with theorchestration engine such that multiple SMEs for a given “family” ofservice (e.g., “database”) can be present in the system. A default SMEcan also be configured for a particular service family on a per-cloudaccount basis.

As shown in FIG. 9, in accordance with an embodiment, the orchestrationand service management components can interface with the virtualizationlayer through a virtualization service 240, plugin 242, andvirtualization API 246 that abstracts supported virtualizationoperations. In accordance with an embodiment that uses OVAB, this APIcan be an OVAB Deployer interface, which enables OVAB Deployer toperform the tasks of assembly creation. In accordance with anembodiment, the orchestration engine/SME can upload and deploysassemblies through the OVAB virtualization API, in addition to managingtheir lifecycle.

To support developer or demonstration scenarios, in accordance with anembodiment, the system can also implement solutions that run on nativeOS processes (i.e., with no virtualization). This capability can beimplemented by providing a “physical plugin”, which implements a portionof the virtualization API.

Elasticity Manager (EM)

FIG. 10 illustrates the use of an elasticity manager, in accordance withan embodiment. As shown in FIG. 10, in accordance with an embodiment,the elasticity manager 260, including an environment manager 262, canuse metric gatherers 264, 265 and alerts 270, e.g., as HK2 contracts, todetermine the health of services running in an environment. Once thestate of the environment is determined, the elasticity manager can takeappropriate actions 272.

In accordance with an embodiment, a metric gatherer is an object thatcollects and maintains metric data about a service periodically. Forexample, a metric gatherer may periodically collect heap statistics suchas used or committed memory; or metrics regarding CPU usage. Generally,the metric gatherers provide information about the state of someresource usage. Metrics can also be provided by external monitoringtools, for example by a Java bean component.

In accordance with an embodiment, an alert object periodically checksthe health of a service in an environment, by analyzing metric datagathered by one or more metric gatherers over a period of time. Forexample, an alert may examine CPU usage for a previous several minutesto determine if the environment is under stress. After the alertdetermines the state of the service or environment, it can execute anaction, such as sending an email, logging a message, sending an event,or scaling-up or scaling-down a service. In accordance with anembodiment, an alert can take multiple actions.

In accordance with an embodiment, the elasticity manager can include aunified Expression Language (EL) engine 268, which allows alerts andmetric gatherers to be specified as EL expressions. In accordance withan embodiment, the elasticity manager allows external EL Resolverobjects 267 to be registered, which enables other types of objects, suchas MBeans or POJOs, to be used in an expression.

Update and Patching of SDPs

In accordance with an embodiment, services can be periodicallymaintained to ensure that they are up-to-date with, e.g., bug fixes,security updates and configuration changes. To help ensure homogeneousenvironments, services should be updated in a timely manner, with thesame set of patches and configuration updates. In accordance with anembodiment, an update is defined to be a change which has to be made tothe system; examples of which include application of a security patch,upgrade of a component, or changing of a configuration value. Dependingon the type of update, some updates may require a service or systemdowntime, while other updates may not require a downtime; and each ofthese scenarios can be taken into account.

Service Domain Replication from Source to Target Service Domain

As described above, in accordance with an embodiment, a PaaS orCloudLogic platform can include a plurality of components, e.g., anadministration server, a cloud platform provisioning/management logic,and virtual assembly builder (VAB) deployer. In accordance with anembodiment, the PaaS platform can be embedded in an application serverruntime, e.g., a WebLogic Server (WLS) runtime, wherein each PaaSplatform component can be implemented as a WLS server application,making a Cloud Logic service domain part of a WLS domain.

As such, replicating a CloudLogic domain (i.e., a service domain) acrossenvironments can include replicating a WLS installation and CloudLogiccomponents, as well as service domain configurations and WLSconfigurations.

In accordance with an embodiment, described herein is a system andmethod for replicating a source service domain to a target servicedomain in a cloud computing platform environment. In accordance with anembodiment, the system comprises a cloud platform component provided asan installable software suite within the cloud environment, thatsupports provisioning of enterprise applications; a test to production(T2P) framework module that includes a plurality of T2P plugins and aPaaS plugin; and a user interface where an administrator or a user caninvoke the plugins to replicate a source service domain to a targetservice domain. The system allows a user to manually customize moveplans for service domain configurations based on the requirements of thetarget service domain, and recreate the configurations in the targetservice domain in accordance with the customized move plans.

In accordance with an embodiment, the domain configurations can includea WLS configuration and a plurality of service domain configurations.Service domain configurations can include a virtualizationconfiguration, a service definition package configuration, a servicetype configuration, a provider type configuration, a service resourcetype configuration, and a tenant structure configuration.

In accordance with an embodiment, each service domain can be part of aWLS domain and can share a domain configuration file, e.g., domain.xml,with the WLS domain. The domain configuration file can include one ormore segments for the WLS configuration and each service domainconfiguration. As an illustrative example, a service type configurationcan have a <service-type> segment in the domain.xml file. The servicetype configuration can also include binary files that containfile-parameters associated with different service type revisions.

In accordance with an embodiment, the system can use movement scripts toinvoke T2P plugins to replicate the middleware (e.g., a WLS server) andCloudLogic components installed in the middleware; and invoke the T2Pplugins and the PaaS plugin to replicate domain configurations (e.g., aWLS configuration and a plurality of service domain configurations),wherein the replication includes extracting move plans for the domainconfigurations to customize and recreate the domain configurations in atarget domain in accordance with the move plans.

In accordance with an embodiment, the system provides the ability tocapture configurations, customize them by editing move plans, andmigrate the configurations to a target service domain. The complex tasksof setting the target service domain and recreating the service domainconfigurations in the target service domain in a correct order can behandled by the T2P framework in conjunction with the PaaS plugin.

FIG. 11 illustrates a system for use in replicating a source servicedomain to a target service domain, in accordance with an embodiment.

As illustrated in FIG. 11, in accordance with an embodiment, the systemincludes a cloud platform component provided as an installable softwaresuite (e.g., a PaaS platform) within a cloud computing environment, thatsupports provisioning of enterprise applications. The cloud platform caninclude a T2P framework module 331, with a PaaS plugin (e.g., aCloudLogic T2P plugin 332), and an administration interface 305 thatincludes a command line interface 307, wherein a user 301 can issuecommands 303 to invoke 309 the T2P framework module.

In accordance with an embodiment, the T2P framework module can include aplurality of Fusion Middleware (FMW) T2P plugins and utilities/tools,which can be used for replicating a source to target service domain,including extracting, copying and pasting binaries, data (applications),and configurations from one domain to another. In accordance with anembodiment, the PaaS plugin is registered with the T2P framework module,so that the T2P framework module can locate and invoke the PaaS plugin.

In accordance with an embodiment, the user can specify, through thecommand line interface, a source service domain 311 that includes domainconfigurations 313 to be replicated, and a target service domain 325 towhich the domain configurations are to be replicated. Domainconfigurations can include a WLS configuration and a plurality ofservice domain configurations, wherein each configuration can beassociated a move plan.

In accordance with an embodiment, the user can invoke the T2P frameworkmodule and the PaaS plugin to create a domain configuration archive 315to contain the domain configurations, and extract the source move plans327 from the configuration archive to a user-specified location, so asto access the move plans to customize them in accordance with therequirements of the target service domain. Once the domain configurationarchive is copied 317 to the target service domain as a domainconfiguration archive 319, the PaaS plugin can be invoked to recreate321 the domain configurations 323 in the target service domain, inaccordance with the customized target move plans 329.

FIG. 12 illustrates a system for use in migrating domain configurationsfrom a source service domain to a target service domain, in accordancewith an embodiment.

In accordance with an embodiment, the domain configuration archive canbe created 314 from the domain configurations using a single command,e.g., CopyConfig.sh, to invoke a WLS T2P plugin of the T2P frameworkmodule. The domain configuration archive, when it is created, caninclude a middleware (e.g., WebLogic Server (WLS)) relatedconfiguration.

In accordance with an embodiment, the WLS T2P plugin can create a moveplan for the WLS configuration, wherein the move plan can include one ormore move plan files that can capture customizable WLS configurationparameters. An example of the contents of the domain configurationarchive can be illustrated in Listing 1:

Listing 1 META-INF/MANIFEST.MFCLONE20130717174007748_CLONE_ALL_SRCID_MAP_FILE_1374108008035Clientjar/cloningclient.jarCLONExxx-J2EECOMPONENT@myCloudDomain/REPOSITORY/ packed.domain.jarCLONExxxJ2EECOMPONENT@myCloudDomain/REPOSITORY/configplans/ moveplan.xmlCLONExxx-J2EECOMPONENT@myCloudDomain/REPOSITORY/configplans/deployment_plans/**.xmlCLONExxx-J2EECOMPONENT@myCloudDomain/REPOSITORY/ldapdata/***.dat

As shown in Listing 1, in accordance with an embodiment, the files underREPOSITORY/configplans are the move plan files. Theconfigplans/moveplan.xml captures the customizable WLS configurations.The customization can also be made directly to theconfigplans/deployment_plans/**.xml files. A domain configurationarchive can include other middleware-related configurations, such asdatabase configurations, startup configurations, and diagnosticsconfigurations.

FIG. 13 further illustrates a system for use in migrating domainconfigurations from a source service domain to a target service domain,in accordance with an embodiment. After the domain configuration archiveis created, the T2P framework module can invoke the PaaS plugin toupdate 316 the domain configuration archive with the service domainconfigurations.

In accordance with an embodiment, the service domain configurations caninclude a virtualization configuration, an SDP configuration, a servicetype configuration, a provider type configuration, a service resourcetype configuration, and a tenant structure configuration, each of whichservice domain configurations can be associated with a move plan (whichcan comprise one or more move plan files), and binary files for storingparameters for the move plan.

FIG. 14 illustrates a system for use in editing move plans, inaccordance with an embodiment.

As shown in FIG. 14, in accordance with an embodiment, each of thesource move plans in the domain configuration archive can be extracted327, using the T2P framework module, to a user specified location. Eachof the extracted source move plan 335 can be retrieved from thespecified location, and edited 336 or customized by the user at thecommand line interface, to generate a corresponding target move plan337, which can be used 329 by the T2P framework module or the PaaSplugin to recreate the domain configurations in the target servicedomain.

In accordance with an embodiment, editing or customizing the move planscan include changing various IP addresses, data source end points, andnode manager configurations; changing the SDP configuration to point toa location where imported SDP binaries files are stored; changing theprovider type configuration to point to a new provider location; and/orchanging the virtualization configuration to point to a new OVM/OVABURL.

In accordance with an embodiment, the move plan customization can beillustrated using, for example, a provider type configuration, as shownin Listings 2 and 3:

Listing 2 <movableComponent> <componentType>Cloud</componentType><componentName>CloudPlatform</componentName> <moveDescriptor><configGroup> <type>PROVIDER_TYPE</type> <configPropertyid=“ProviderType1”> <configProperty> <name>Provider Type Name</name><value>OracleDBProvider</value> <itemMetadata><dataType>STRING</dataType> <scope>READ_ONLY</scope> </itemMetadata></configProperty> <configProperty> <name>Configuration Plan</name><value>cloudlogic/oracledbprovider.xml< /value> <itemMetadata><dataType>STRING</dataType> <scope>READ_WRITE</scope> </itemMetadata></configProperty> </configGroup> </moveDescriptor> </movableComponent>

Listing 3 <servicetype name=“OracleDBProvider” type=“PROVIDER_TYPE”sdpref= OracleDB”> <st-revision default-revision=“ true”> <propertyname=“connectionAttributes” value=“create=true”></property> <propertyname=“user” value=“APP”></property> <property name=“password”value=“APP”></property> <property name=“portNumber”value=“1527”></property> <propertyname=“databaseName”value=“sampledb”></property> <property name=“hostName”value=“localhost”></property> </st-revision> </servicetype>

As shown in Listing 2, in accordance with an embodiment, the move planfile can include a reference to another move plan file, i.e., a providertype configuration file “cloudlogic/oracledbprovider.xml”. Theoracledbprovider.xml as shown in Listing 3 can be edited and customizedto point to the new provider end point. Move plan files for otherconfigurations can be similarly edited.

FIG. 15 further illustrates a system for use in migrating domainconfigurations from a source service domain to a target domain, inaccordance with an embodiment.

In accordance with an embodiment, to replicate domain configurations,middleware and SDP binaries associated with the domain configurationsalso need to be replicated. As shown in FIG. 15, in accordance with anembodiment, a source binary archive 338, one or more source SDP binaryfiles 339, and the source domain configuration archive 315 can be copied343, 345, and 347 to the target service domain as a target binaryarchive 341, target SDP binaries 340, and a target domain configurationarchive 319, either via FTP or other migration tools of the T2Pframework module.

In accordance with an embodiment, the source binary archive can becreated from an application server installation using a utility of theT2P framework module. As an illustrative example, a script, such as thecopyBinary script of the T2P framework module, can be used to preparethe source application server installation and create the binaryarchive. The script can record the file permissions of the applicationserver installation and the ClouldLogic components in the applicationserver installation.

In accordance with an embodiment, a T2P utility, e.g., pasteBinary.sh,can be used to recreate the middleware from the binary archive in thetarget service domain, where the T2P utility can check that theprerequisites are met in the target service domain, extract files fromthe archive file, register middleware and CloudLogic components, andrestore the file permissions and relink any files if necessary.

In accordance with an embodiment, the SDP binaries can be copied using,e.g., an export-SDP command, which can convert the SDP binaries into aplurality of smaller ZIP files for easy replication. The SDP binaries,after being copied to the target service domain, can be reloaded andinstalled, to support service cloning and the recreation of the servicedomain configurations.

FIG. 16 illustrates setting up a target service domain, in accordancewith an embodiment. As shown in FIG. 16, in accordance with anembodiment, the T2P framework module can set up the domain 349 withWLS-specific customizations made in the move plan 353. When setting upthe target service domain, the WLS configuration can be recreated in adomain configuration file and one or more application servers can bestarted.

FIG. 17 illustrates recreating domain configurations in a target servicedomain, in accordance with an embodiment.nnAs shown in FIG. 17, inaccordance with an embodiment, after the target service domain is set upand started, the T2P framework module can invoke the PaaS plugin torecreate the service domain configurations 359, in accordance with thecustomizations specified in the move plans.

In accordance with an embodiment, recreating a service domainconfiguration includes recreating the configuration in a domainconfiguration file, e.g., domain.xml, and recreating a correspondingdirectory for storing binary files that contain the file parameters forvarious revisions of the configuration. When recreating the service typeconfiguration, a validation can be performed to check if the SDPreferences specified in the service type configuration exist. Once thedomain configurations are recreated the target service domain, servicescan be cloned from the source service domain to the target servicedomain.

As illustrated above, in accordance with an embodiment, the T2Pframework module provides the ability to capture and move theconfigurations all at once. The complex tasks of setting up the targetservice domain with the customized WLS configuration and recreating theservice domain configurations in the correct order can be handled by theT2P framework module, in conjunction with the PaaS plugin.

FIG. 18 illustrates a method of replicating a source service domain to atarget service domain, in accordance with an embodiment. As shown inFIG. 18, in accordance with an embodiment, at a first step 430, one ormore computers including a cloud environment and a PaaS platformcomponent (PaaS platform) executing thereon, are provided.

At step 432, a T2P framework module with a PaaS plugin and a pluralityof T2P plugins and utilities and a user interface where the plugins andutilities can be invoked, are provided.

At step 434, a domain configuration archive that includes a middlewareconfiguration and service domain configurations from a source servicedomain can be created. When it is first created, the domainconfiguration archive can include the middleware configuration, and canbe subsequently updated with the service domain configurations.

At step 436, the move plan of each configuration in the domainconfiguration archive is extracted and edited with customizations inaccordance with a target service domain.

At step 438, the domain configuration archive is copied to the targetservice domain.

At step 440, the configurations in the domain configuration archive arerecreated in the target service domain in accordance with the customizedmove plans.

Service Import/Export

In accordance with an embodiment, described herein is a system andmethod for exporting and importing a PaaS service and associatedconfigurations across service domains are provided. The system comprisesa cloud platform component provided as an installable software suitewithin a cloud environment; a test to production (T2P) framework modulethat includes a PaaS plugin and a plurality of T2P plugins and tools;and a user interface where the plugins and tools can be invoked toexport domain configurations from a source service domain, and importthe domain configurations to a target domain. In accordance with anembodiment, the system further includes a service provider interface(SPI) that can be implemented by an SME of each service housed in aservice domain, to provide service backup and restore functionalitiesfor exporting and importing that service.

In accordance with an embodiment, the system further includes a serviceprovider interface (SPI) that can be implemented by an SME of eachservice housed in a service domain, to provide service backup andrestore functionalities for exporting and importing that service.Post-provision changes from a source service in a source service domaincan be extracted to create a service backup file, which can be exportedto a target service domain and applied to a target service created froma same SDP used for creating the source service.

In accordance with an embodiment, domain configurations, e.g., a WLSconfiguration and a plurality of service domain configurations, can bereplicated across service domains to support service exporting andimporting. The domain configurations can be extracted from the sourceservice domain, and stored in a domain configuration archive, wherein amove plan for the WLS configuration references each of the move plansfor the service domain configurations. The domain configuration archivecan be exported to the target service domain, and each configuration isextracted from the domain configuration archive and recreated in thetarget service domain.

Export from a Source Service Domain

FIG. 19 illustrates a system for use in exporting a service from asource service domain to a target service domain, in accordance with anembodiment.

As shown in FIG. 19, in accordance with an embodiment, the systemcomprises a cloud platform component (e.g., a PaaS platform 100)provided as an installable software suite within the cloud environment10; a T2P framework module 331 that includes a PaaS plugin 332 and aplurality of T2P plugins and tools; and a command line interface 307within an administration interface 305, wherein a user 301 can issuecommands 303 to be executed at the interfaces, to interact 309 with asource service domain 311.

In accordance with an embodiment, a service 501 can include a serviceapplication, e.g., Fusion Middleware application, one or more userapplications deployed to the service application and associatedconfigurations. Post-provision changes made to the service, such as theuser applications and post-provision configurations 509, can beextracted from the service and saved to a service backup file 503. Inaccordance with an embodiment, the service backup file can be createdusing the service's SME.

In accordance with an embodiment, the SME can utilize the T2P plugins toextract the post-provision changes from the service, and use the servicebackup functionality inherited from the SPI to save the changes to thebackup file. An example backup interface of the SPI is illustrated byListing 4:

Listing 4 Package com.oracle.cloudlogic.service.spi; importcom.oracle.cloudlogic.service.api.Service; importcom.oracle.cloudlogic.service.api.ServiceBackup;@org.jvnet.hk2.annotations.Contract public interfaceServiceBackupManager { /**  * Take the backup of the service.  * @paramservice The service whose backup needs to be taken.  * @return Theservice backup.  */ ServiceBackup backup (Service service); /**  *Restore the backed up data to the service. * @param service Service towhich the backup needs to be applied.  * @param backup The servicebackup  * @return true if successful, false otherwise.  */ booleanrestore (Service service, ServiceBackup backup); // Other existingmethods } package com.oracle.cloudlogic.service.api;@org.jvnet.hk2.annotations.Contract public class ServiceBackupimplements Serializable { // Name of the service for which this backupwas taken. private String serviceName; // Time at which the backup wastaken private Date timestamp; //Service name and timestamp together forma unique backup id. // Backup description  String description; privateMap<String, File> backupFiles = new HashMap( ); public ServiceBackup(String serviceName, Date timestamp, String description) {this.serviceName = serviceName; this.timestamp = timestamp;this.description = description; } public String getServiceName( ) {return serviceName; } public Date getTimestamp( ) { Return timestamp; }public Map <String, File> getBackupFiles( ) { this.backupFiles =backupFiles; } public void addBackupFile (String name, File file) {backupFiles,put (name, file); } }

As shown in Listing 4, in accordance with an embodiment, the SPIinterface can store information about a service, such as the name,timestamp, and a description of the service. User applications andpost-provision configurations can be stored in a data structure, e.g., aMap, for easy retrieval of the information after the backup file istransferred to a target service domain.

As further shown in FIG. 19, the service can be associated withoperating system and middleware patches made after the service isprovisioned. Binary patches 513 can be saved to binary files 339 of anSDP used for creating the service.

In accordance with an embodiment, a WLS plugin of the T2P frameworkmodule can be used to create a domain configuration archive file 315, tocontain information extracted from domain configurations 313. Domainconfigurations can include one or more configuration files, e.g.,doman.xml, and one or more binary files, e.g., for holding fileparameters for the configuration files. Each of the plurality of domainconfigurations, such as a service type configuration and a WLS-relatedconfiguration, can have one or more corresponding segments in the domainconfiguration files. These segments can define customizable parametersfor a cross-domain migration, and can be extracted out as move planfiles.

In accordance with an embodiment, the domain configuration archive 315can be created to initially include a middleware (e.g., WLS) relatedconfiguration 507, and subsequently updated with service domainconfigurations 505. The creation and updating of the domainconfiguration archive can be performed respectively by the T2P frameworkmodule and the PaaS plugin. In accordance with an embodiment, a command,e.g., copyConfig.sh, can be executed at the command line interface tosequentially invoke the framework module and the PaaS plugin.

In accordance with an embodiment, the domain configuration archive caninclude both move plans and associated binary files 517 for theconfigurations with the exception of the SDP configuration. Sizes of thebinary files associated with the SDP configuration can be very large andcan be extracted 515 and stored in a separate SDP binary file 339,instead of the domain configuration archive. The move plan for the SDPconfiguration can be stored in the domain configuration archive.

In accordance with an embodiment, a service backup file, the domainconfiguration archive and the SDP binary files can exported 519, e.g.,by FTP, to a target service domain.

FIG. 20 illustrates a system for creating a domain configuration archivefor use in exporting a service from a source service domain to a targetservice domain, in accordance with an embodiment.

As shown in FIG. 20, the domain configurations can include domainconfiguration files 523, and binary files 521 for providing fileparameters for the configuration files.

In accordance with an embodiment, when creating the domain configurationarchive, the T2P framework module can extract 539 the move plan 515 forthe middleware configuration 507 from the domain configuration files,and store the move plan in the domain configuration archive. Similarly,move plans for the service domain configurations can be extracted 543,545 and stored in the configuration archive. When extracting aconfiguration from the domain configuration files, the system canconvert that configuration into one or more ZIP files, add the ZIP filesto the domain configuration archive, extract the move plan from the ZIPfiles, and store the move plan in the domain configuration archive.

As an illustrative example, in accordance with an embodiment, the PaaSplugin can invoke a T2P utility, e.g., list-service-types, to displaythe service types to be exported; and for each displayed service type,invoke another T2P utility, e.g., export-service-type, to convert theservice type into a ZIP file. The ZIP files can be added to theconfiguration archive under a directory, and a move plan 527 can beextracted from the ZIP files and stored in a separate directory 505 inthe domain configuration archive. The binary files 526 for the servicetype configuration 525, which can include different revisions to theservice type, can be extracted 541 from the domain configurations.

As further shown in FIG. 20, in accordance with an embodiment, the SDPconfiguration 529 in the domain configuration archive only includes amove plan 531, and does not include associated binary files. Because ofthe large size of the binary files associated with the SDP, which caninclude service-definition.xml, file parameter binaries, SME JAR and itsrevisions, and virtual assemblies, the SDP binaries can be exported tothe target service domain separately. Once the move plans for theservice domain configurations are stored in the domain configurationarchive, the move plan of the middleware configuration can be updated toreference 535, 537 each of the service domain configuration move plans.

An example updated domain configuration archive structure is illustratedin Listing 5 below:

Listing 5 META-TNF/MANTFEST.MFCLONE20130717174007748_CLONE_ALL_SRCTD_MAP_FTLE_1374108008035clientjar/cloningclient.jarCLONExxx-J2EECOMPONENT@myCloudDomain/REPOSITORY/ packed_domain.jarCLONExxx-J2EECOMPONENT@myCloudDomain/REPOSTTORY/configplans/moveplan.xmlCLONExxx-J2EECOMPONENT@myCloudDomain/REPOSTTORY/configplans/deployment_plans/**.xmlCLONExxx-J2EECOMPONENT@myCloudDomain/REPOSTTORY/ldapdata/**.datCLONExxx-J2EECOMPONENT@myCloudDomain/REPOSTTORY/configplans/cloudlogic/**.xmlCLONExxx-J2EECOMPONENT@myCloudDomain/REPOSTTORY/cloudlogic/ <<binaryfiles>>

As shown in Listing 5, in accordance with an embodiment, binary filesand move plans for the service domain configurations can be stored intwo separate directories. As further shown in Listing 5, the move planof the middleware configuration is located in a different directory fromthe move plans of the service domain configurations.

In accordance with an embodiment, the packed_domain.jar in Listing 5 canhave the structure as shown in Listing 6:

Listing 6 config/ config/config.xml config/cloudserver/..config/coherence/.. config/diagnostics/.. config/jdbc/.. common/db/..config/deployments/.. config/fmwconfig/.. config/startup/.. ..other xmlfiles like database.xml, security.xml, confignodemanager.xml,..etc..consoleext/.. ab_instance/..

Import to a Target Service Domain

FIG. 21 illustrates a system for use in importing a service to a targetservice domain, in accordance with an embodiment.

As shown in FIG. 21, a service backup file 549, SDP binaries 340, and adomain configuration archive 319 including service domain configurations551 and a middleware configuration 553, have been imported 547 to thetarget service domain.

In accordance with an embodiment, the T2P framework module can beinvoked to set up the target service domain with the WLS specificcustomizations made in the move plan 329 and using the middlewareextracted from the imported binary archive. Once the T2P frameworkmodule finishes creating the target service domain, the PaaS plugin canbe invoked to recreate 567 the service domain configurations. Recreatinga configuration can include creating the configuration and variousrevision objects in a domain configuration file 323, e.g., domain.xml,and creating a corresponding directory to the associated binary fileparameters.

As an illustrative example, in accordance with an embodiment, a servicetype configuration can be recreated in accordance with the correspondingedited move plan by validating if the SDP references specified in theservice type and the SDP revisions corresponding to the service typerevisions exists; upon validation, using configuration modularity torecreate the service type and service type revision objects in thedomain configuration file; and, creating a service type directory in thetarget service domain. In accordance with an embodiment, the SDPconfigurations must have been recreated and the SDP binaries loaded tothe target service domain, before the service type configuration can berecreated therein.

In accordance with an embodiment, the SDP configuration can be importedusing an import SDP utility 569, which can recreate 571 the SDPconfiguration and associated revisions in the target service domain,copy the service-definition.xml and associated files to an appropriatedirectory in the domain, deploy the SME with its revisions from the SDPbinaries, and upload and register virtual assemblies from the SDPbinaries with the PaaS platform. To import the source service 343, thedeployed SME can be invoked to create 575 a new service 580 inaccordance with the SDP binaries that has been used to create the sourceservice, and apply the service backup 579 imported from the sourceservice domain to the new service. The updated new service can include aservice application and user applications 581, and post-provisionconfigurations 583.

FIG. 22 illustrates a method of exporting a service from a sourceservice domain to a target service domain, in accordance with anembodiment. As shown in FIG. 22, in accordance with an embodiment, atstep 630, one or more computers including a cloud environment and a PaaSplatform component executing thereon, are provided.

At step 632, a T2P framework module that includes a PaaS plugin and aplurality of T2P plugins and utilities and a user interface where theplugins can be invoked, are provided.

At step 636, the domain configurations can be extracted using theplurality of plugins and utilities from the source service domain andstored in a domain configuration archive, where a move plan of themiddleware configuration references each move plan of the other domainconfigurations.

At step 638, the SDP binaries used to create a source service isextracted from the source service domain, wherein the SDP binaries caninclude binary patches to the operating system and middleware to whichthe source service is deployed.

At step 640, a backup of the source service that includes userapplications and post-provision configurations to the service is createdusing the SME of the source service.

At step 642, the domain configuration archive, SDP binaries, and servicebackup file are exported.

FIG. 23 illustrates a method of importing a service to a target servicedomain, in accordance with an embodiment. As shown in FIG. 23, inaccordance with an embodiment, at step 660, one or more computersincluding a cloud environment and a PaaS platform component executingthereon, are provided.

At step 662, a T2P framework module that includes a PaaS plugin and aplurality of T2P plugins and utilities and a user interface where theplugins can be invoked, are provided.

At step 666, a target service domain is set up using the middlewareconfiguration and the middleware binaries in accordance with acorresponding edited move plan.

At step 668, the SDP configuration is recreated in accordance with acorresponding edited move plan, including recreating the SDPconfiguration and associated revisions in a domain configuration file,deploying the SME with its revisions, and uploading and registeringvirtual assemblies with the target service domain.

At step 669, a plurality of other service domain configurations arecreated in accordance with their respective edited move plan.

At step 670, a new service is created in the target service domain usingthe imported SDP binaries.

At step 672, the imported service backup file is applied to the newservice.

Service Cloning

In accordance with an embodiment, described herein is a system andmethod for providing a clone a service in a cloud platform environment.The system can clone a source service within a service domain or acrossservice domains, by creating a new service from a same servicedefinition package used for creating the source service, extractingpost-provision changes from the source service, e.g., user applicationsand post-provision configurations, and applying the changes to the newservice.

In accordance with an embodiment, the system provides a generic andextensible solution to service cloning, and can be used to clone anyPaaS service, e.g., Database service, Java EE service and SOA service,if the supplier of such a service implements a plugin (i.e. a servicemanagement engine) using a service provider interface (SPI). The SME ofeach service in a service domain can implement the SPI to provideservice backup and restore functionalities when a service is beingcloned, and is provided with complete control in determining changesthat have been made to the source service, and in choosing the changesthat need to be replicated to a target service.

Furthermore, in accordance with an embodiment, the system can provideautomatic re-wiring of infrastructure and application dependencies whilecloning a service. By way of illustration, a WebLogic service, which isassociated with a test database in a test environment, can beautomatically switched to a production database when cloned to aproduction environment. As such, under the above-described approach, aservice cloning operation can be highly automatable and require minimalmanual intervention.

In accordance with an embodiment, the above-described approach can beused to create a clone service within a same domain, where the cloneservice can run on the same virtualization configuration and use thesame provider types as the source service, or run on a differentvirtualization pool and use different provider types for variousprovider dependencies from the source service. Alternatively, a sourceservice can be cloned from a source service domain to a target servicedomain when the SDP, service types and provider types have been importedfrom the source service domain to the target service domain.

In accordance with an embodiment, the service cloning feature provides ameans of moving a tested/tuned service into production, ensuresconsistency of configurations of services in a large enterprise, andhelps the account administrator prevent “configuration sprawl”.

FIG. 24 illustrates a high level overview of cloning a service within aPaaS platform, in accordance with an embodiment.

As shown in FIG. 24, in accordance with an embodiment, a cloud platformcomponent (e.g., a PaaS platform 100) can be provided as an installablesoftware suite within a cloud environment 10. A command line interface307 within an administration interface 305 can be used by a user 301 toissue a service cloning command 303 to interact 309 with the PaaSplatform.

In accordance with an embodiment, a source service 675A, when originallycreated, can include system applications 677A and configurations 679A,and can be deployed to a middleware application 681A, e.g., a WebLogicserver. The middleware application can be further deployed on anoperating system 683A executing on a hardware system 685A.

In accordance with an embodiment, additional changes 687 can be made tothe provisioned service, where the additional changes can include userapplications, additional configurations, tuning, performanceoptimizations, patches to the operating system and the middleware.

For example, service S1+ (e.g., 675B) illustrates the originally createdservice to which the post-provision changes have been applied. Theservice S1+ can include the additional changes 677B, configurations andadditional configurations 679B, where these applications andconfigurations are deployed to a middleware application 681B executingon an operating system 683B, and where the operating system is installedon a hardware system 685B. The service S1+, with the additional changes,can be a source service to be cloned.

As a first step in cloning the source service, the user can issue aservice cloning command through the commandline interface to recreate688 a service 675C with the SDP used to create the original service(i.e. Service S1). In accordance with an embodiment, the SDP can carrythe binary patches that have been applied to the source service to becloned (i.e. S1+). Accordingly, the service recreated (i.e. S1′) caninclude the patches, as shown by 681C and 683C. System applications 677Cand configurations 679C, which are deployed to the recreated serviceprovisioned on a hardware system 685C, can be the same as those deployedto the service as originally created (i.e. S1).

In accordance with an embodiment, the user can extract 689 theadditional applications and configurations from the source service to astorage 690, e.g., a file, and apply 691 the modifications/changes tothe recreated service S1′. With the additional changes applied, therecreated service can be considered a cloned copy 675D of the sourceservice. The cloned copy can include the same applications,configurations and patches as the source service, as shown by 677D,679D, 681D, 683D, and 685D.

FIG. 25 illustrates a system for use in providing a clone service withina service domain, in accordance with an embodiment.

As shown in FIG. 25, in accordance with an embodiment, the systemcomprises the cloud platform component, an SDP 703, an associated SME707 that has implemented the SPI, and a service orchestration engine(OE) 705 that can invoke the SME to create services based on the SDP.

In accordance with an embodiment, the command line interface within theadministration interface can be used by the user to issue the servicecloning command to interact with a service domain 701.

In accordance with an embodiment, the service cloning command canspecify a source service 711 to be cloned, wherein the source servicehas been created 709 from the SDP. In accordance with an embodiment, thesource service can include a service application, user applications, andservice configurations. Service configurations can includepost-provision configurations such as JVM options, in addition to e.g.,virtualization configurations and provider type configurations forvarious provider dependencies. The source service can contain binarypatches to the middleware and the operating system on which the sourceservice runs.

In accordance with an embodiment, the orchestration engine can invokethe SME to create a service backup 715, using the extracted userapplications and post-provision configurations 713 from the sourceservice, create 719 a target service 721 using the same SDP that hasbeen used to create the source service, and apply the service backup 717to the newly created target service. After the service backup has beenapplied to the target service, the target service can be considered aclone of the source service.

In accordance with an embodiment, the user interface can expose one ormore service types to be selected by the user to clone the sourceservice. When a request is received to clone the source service using aspecified service type, the system can check whether the specifiedservice type is a clone of the service type for the source service. Ifthe specified service type fails the check, the service cloning commandcan terminate. Using a cloned service type to create a target servicecan enable the target service to run on a different virtualization pooland with different provider types for various provider dependencies fromthe source service.

In accordance with an embodiment, a service type can be cloned within aservice domain using a command that specifies a source service type, atarget service type, a virtualization configuration and a plurality ofdependency types for provider dependencies. The system can validatewhether the specified virtualization option is of the samevirtualization type as that of the source service type, whether theprovider type chosen for each provider dependency belongs to a correctfamily. If all the validations succeed, the system can call an SDPmanager to find the SDP used for creating the source service type, loadthe SDP to the specified virtualization configuration if it is notalready loaded, and create the desired service type from the loaded SDP.

FIG. 26 illustrates creating a service backup within a service domain,in accordance with an embodiment.

As shown in FIG. 26, in accordance with an embodiment, the SME can useone or more T2P plugins of the T2P framework module to extract 713post-provision changes, e.g., user applications 725 and post-provisionconfigurations 727 to the source service, and create a backup file 715out of the changes. The service backup can include a move plan for thesource service but not include a service application 723 of the sourceservice.

In accordance with an embodiment, the SME, by implementing the SPIinterface, can compute configuration and application changes that aremade to the source service through the administration/configurationtools provided to the user. As an illustrative example, theadministrator can change the configurations of a Java service throughthe service's administration console. If the SME fails during extractingthe application and configuration changes, the whole clone-serviceoperation can terminate, and the system can be restored to the stateprior to the clone-service initiation.

FIG. 27 further illustrates a system for use in providing a cloneservice within a service domain, in accordance with an embodiment.

In accordance with an embodiment, the post-provision changes to thesource service can include binary patches 731 to the operating systemand the middleware that host the source service. The binary changes canbe stored in the SDP binaries used to create the source service. Inaccordance with an embodiment, the SDP binaries, with the binarypatches, can be used to create 719 a target service 735 with a serviceapplication 737.

FIG. 28 further illustrates a system for use in providing a cloneservice within a service domain, in accordance with an embodiment.

As shown in FIG. 28, in accordance with an embodiment, the system caninvoke the SME to apply the service backup 717 to the target service.Applying the service backup to the target service can include extractinga move plan from the target service using T2P tools; computing thedifferences between the move plan in the source service backup and themove plan from the target service and merging the two move plans; andapplying the source service backup to the target service in accordancewith the merged move plan. When merging two move plans, the values ofelements with, e.g., READ_WRITE scope in the source service move plancan be changed to reflect the new values required by the target service.

After the service backup is applied, the target service can include userapplications 739 and post-provision configurations 741, in addition tothe service application and its associated configurations made when theservice is provisioned.

In accordance with an embodiment, the SPI implemented by the SME can bedefined generically so that it can provide the SME with the flexibilityof choosing other approaches for extracting/applying configurations andapplications from the source service to the target service without usingthe T2P tools and utilities. As an illustrative example, the SME canchoose the following tools as alternatives:

Service specific tools: For example, the Java Service SME can create adomain extension template and apply the domain extension template to thetarget service.

OVAB utilities: The SME can use OVAB's disk snapshotting to snapshootthe disk where configurations and application data are stored and applythe configurations and data to the target service. In accordance with anembodiment, snapshotting the service's disk using OVAB can includeupdating the service's internal configurations in the snapshotted diskby the SME.

FIG. 29 illustrates cloning a service to run on a differentvirtualization, in accordance with an embodiment.

As illustrated in FIG. 29, in accordance with an embodiment, a sourceservice 742A can be provisioned to a virtualization pool 749A based on avirtualization provider VC1 745A created by an account administrator. Inaccordance with an embodiment, the source service can be created from asource service type 743A that is derived from a source SDP 744A.

In accordance with an embodiment, in order to create 746 a clone service742B of the source service to run on a different virtualization on adifferent virtualization pool 749B, a cloned copy 743B of the sourceservice type can be created 747 with specified provider dependenciesthat includes a dependency on a different virtualization provider VC2745B. The source SDP 748 can be loaded to the different virtualizationas a cloned SDP 744B and used 748 to create the cloned service type.

After the cloned service type is created, the account administrator canrun a clone-service command 746, e.g., “cadmin clone-service--sourceservice s1 --servicetype st1_clone s1_clone”, to clone thesource service. In this command, the service s1 is the “source service”,the service s1_clone is the “target service”, and the argument‘--servicetype’ is optional. When the ‘--servicetype’ is not specified,the target service would run on the same virtualization as the sourceservice and would use the same provider types as the source service forsatisfying its provider dependencies. When the ‘--servicetype’ isspecified, however, a validation can be performed to make sure that thespecified service type is a clone of s1's service type (using theproperty set in the st1_clone).

In accordance with an embodiment, as part of the service cloningprocess, a command, e.g., “create-service --servicetype st1--virtualization vc1 s1”, can be executed to create a new service(target service) using the specified service type (i.e. st1_clone), sothat the created service can run in the desired virtualizationconfigurations and with the desired provider dependencies. If the“--servicetype option” is not specified, the service type of the sourceservice s1 can be used. The create-service command can be called eitherthrough ReST or through the commandline interface. Configuration andapplication changes can be extracted from the source service using anSME of the source service, and applied to the target service (i.e.st_clone) by invoking the SME of the target service.

The above-described steps in the service cloning process can beincorporated as part of the implementation of the clone-service command.

In accordance with an embodiment, each service, e.g., the source serviceand the target service, can have T2P tools/plugins installed in theservice, so that the SME of the service can use the tools/plugins toextract the configuration and application changes from the sourceservice, and apply the extracted changes to the target service. The T2Ptools can provide utilities such as copyConfig, makeMovePlan andpasteConfig; and an SME can process the move plan before pasting it tothe target service.

FIG. 30 illustrates cloning a service across service domains, inaccordance with an embodiment.

As shown in FIG. 30, in accordance with an embodiment, to clone aservice from a source service domain to a target service domain, the SDP750, the domain configurations 753 and the source service backup 755 canbe imported 765, 767, 769 from the source service domain to the targetservice domain as an imported SDP 757; domain configurations 759recreated; and a source service backup 761 imported. A target service763 can be created 773 from the imported SDP in the target servicedomain, and the imported source service backup can be subsequentlyapplied 771 to the target service.

FIG. 31A is a sequence diagram that illustrates cloning a service withina service domain, in accordance with an embodiment. As shown in FIG.31A, in accordance with an embodiment, at step 812, an accountadministrator can issue a service cloning command, e.g., “cadminclone-service --sourceservice S1 --servicetype st1_clone S1_clone”, to aservice cloning framework 801 to clone a source service 811.

At step 817, which occurs in a first stage 813 of a service cloningprocess, a cloning framework 801, upon receiving the service cloningcommand, can validate the service type specified by the “--servicetype”option in the command to examine whether the specified service type is aclone of the service type of the source service. If the specifiedservice type passes the validation, a target service can be createdusing the specified service type. If a service type is not specified inthe service cloning command, the service type of the source service canbe used to create the target service.

At step 819, the cloning framework invokes an orchestration engine 803in a service domain to create the target service 852 using the desiredservice type.

At step 821, the orchestration engine can invoke an SME 805 to createthe target service.

At step 823, the target service can be returned to the orchestrationengine, which in turn can return the target service to the cloningframework at step 825.

At step 827, which occurs in a second stage 815 of the serve cloningprocess, the cloning framework can operate to invoke the SME of thesource service via the orchestration engine.

At step 829, application and configuration changes from the sourceservice can be extracted by, e.g., calling theServiceBackupManager.backup( ) interface of the SME.

At step 831, the SME can further invoke the T2P tools/plugins installedin the source service to perform the extraction.

At step 833, the source service can return the extracted application andconfiguration changes to the SME of the source service, along with amove plan MP1.xml.

At step 835, the SME of the source service can create a backup file fromthe extracted changes and return the backup file to the cloningframework.

FIG. 31B is a continuation of the sequence diagram from FIG. 31A, inaccordance with an embodiment. As shown in FIG. 31B, the extractedapplication and configuration changes from the source service can beapplied to the target service in a third stage 837 of the servicecloning process.

At step 839, the cloning framework can invoke the SME of the targetservice created in FIG. 31A. The SME can be the same as the SME of thesource service.

At step 841, the ServiceBackupManager.restore( ) interface of the SME ofthe target service can be used to apply the backup file of the sourceservice, to the target service.

At step 843, the SME of the target service can extract configurationsand applications from the target service using the T2P tools inside thetarget service.

At step 845, the extracted configurations and applications along with amove plan, e.g, MP1_clone.xml, can be returned to the SME of the targetservice.

At step 847, the target service SME can compute the differences betweenthe move plan of the source service and the move plan of the targetservice, and merge the two move plans into a new move plan.

At step 849, the backup file of the source service can be applied to thetarget service using the new move plan.

At step 851, the target service with the backup file applied thereto canbe returned to the cloning framework, and the target service, with theadditional changes applied thereto, becomes a cloned copy 853 of thesource service.

In accordance with an embodiment, an exemplary snippet of a move planfrom a service is shown in Listing 7:

Listing 7 <movePlan> <movableComponent><componentType>J2EEDomain</componentType><componentName>base_domain</componentName> <version>12.1.2.0.0</version><id>CLONE20130315163055755</id> <moveDescriptor> <configProperty><name>Startup Mode</name> <value>PRODUCTION</value> <itemMetadata><dataType>STRING</dataType> <scope>READ_WRITE</scope> </itemMetadata></configProperty> <configGroup> <type>SERVER_CONFIG</type><configProperty id=“Server1”> <configProperty> <name>Server Name</name><value>AdminServer</value> <itemMetadata> <dataType>STRING</dataType><scope>READ_ONLY</scope> </itemMetadata> </configProperty><configProperty> <name>Listen Address</name> <value>10.178.246.3</value><itemMetadata> <dataType>STRING</dataType> <scope>READ_WRITE</scope></itemMetadata> </configProperty> ... </configProperty> ...<configGroup> <type>DATASOURCE</type> <configProperty id=“DataSource1”><configProperty> <name>DataSource Name</name> <value>JDBC DataSource0</value> <itemMetadata> <dataType>STRING</dataType><scope>READ_ONLY</scope> </itemMetadata> </configProperty><configProperty> <name>Url</name> <value>jdbc:derby://localhost:1528/sampledb;ServerName=localhost; databaseName=sampledb</value><itemMetadata> <dataType>STRING</dataType> <scope>READ_WRITE</scope></itemMetadata> </configProperty> ... </configGroup> ...</moveDescriptor> </movableComponent> </moveplan>

In accordance with an embodiment, the values of the elements withREAD_WRITE scope can be changed by an SME to reflect the new valuesrequired by the target service.

FIG. 32 is a sequence diagram illustrating cloning a service acrossservice domains, in accordance with an embodiment. As shown in FIG. 32,in accordance with an embodiment, at step 877, an account administrator861 can send a request to an SME 863 of a source service in a sourceservice domain 873 for extracting configuration and application changes(e.g., user applications and post-provision configurations) of a sourceservice (S1) 865.

At step 879, the SME of the source service invokes one or more T2P toolsof the source service.

At step 881, the T2P tools of the source service are used to extractuser applications and post-provision configurations from the sourceservice.

At step 883, the source service returns the extracted configuration andapplication changes, along with a move plan (e.g., MP1.xml), to the SMEof the source service.

At step 885, the SME of the source service creates a backup copy of thesource service, which can include the extracted configuration andapplication changes and the move plan, and return the backup copy to theaccount administrator.

At step 887, the account administrator sends a request to anorchestration engine 867 in a target service domain 875, for creating atarget service (S1′) using an imported SDP/service type of the sourceservice and associating the new service with new provider types in thetarget service domain.

At step 889, the orchestration engine invokes an SME 869 in the targetservice domain to create the target service 871.

At steps 891, 893 and 895, the target service S1′ is created andreturned to the account administrator through the SME and theorchestration engine in the target domain.

At step 898, the account administrator requests the SME in the targetdomain to apply the backup of the source service to the created targetservice.

At steps 902 and 903, the SME in the target domain invokes the T2P toolsinside the new service to extract system applications and configurationsfrom the new service, along with a move plan MP1′.xml.

At step 905, the SME in the target domain computes the differencesbetween the move plan of the source service and the move plan of thecreated new service, and merges them into a new move plan.

At step 909, the SME in the target domain applies the backup of thesource service to the created target service using the new move plan.

At step 911, the SME in the target domain returns the created targetservice that includes the backup of the source service to the accountadministrator, where the created target service can include the serviceapplication and configurations, as well as user applications andpost-provision configurations. The target service, with the additionalchanges applied thereto, becomes a cloned copy 913 of the sourceservice.

FIG. 33 illustrates a method for providing a clone service within aservice domain, in accordance with an embodiment. As shown in FIG. 33,at a first step 930, one or more computers including a cloud environmentand a PaaS platform component (PaaS platform) executing thereon, areprovided.

At step 932, a new service is created using the SDP that has been usedfor creating a source service.

At step 934, applications and configurations added to the source serviceafter the source service is provisioned are extracted, e.g. userapplications and related configurations.

At step 936, the extracted applications and configurations from thesource service are applied to the new service.

FIG. 34 illustrates a method for providing a clone service acrossservice domains, in accordance with an embodiment. As shown in FIG. 34,at step 972, applications and post-provision configurations added to asource service after the source service is provisioned in a sourceservice domain, are extracted.

At step 974, a backup of the source service is created using theextracted applications and configurations, and copied to a targetdomain.

At step 978, a new service is created in a target service domain usingan imported SDP and service type used for creating for the sourceservice.

At 984, an SME in the target service domain computes the differencesbetween a move plan associated with the source service and a move planassociated with the new service, and merge the two plans into a new moveplan.

At step 986, the backup of the source service is applied to the newservice using the new move plan to create a clone service.

Public Interfaces for Service Cloning

In accordance with an embodiment, provided below are example interfacesfor service cloning as described above. The example interfaces areprovided for the purposes of illustration and description, and are notintended to be exhaustive or to limit the invention to the precise formsdisclosed.

The clone-service-type command: Cloning of the service type is achievedusing export-service-type and import-service-type commands, and there isno need to have explicit clone-service-type command. An example ofcloning a service type can be:

$padmin export-service-type --servicetype st1 st1.zip $padminextract-move-plan -moveplan st1.xml st1.zip $; edit the extract moveplan to modify the parameters. $padmin import-service-type -moveplanst1.xml st1.zip

The clone-service command: The clone-service command can be exposed tothe cloud account administrator to clone a service within a CloudLogicdomain. The command syntax can be:

cadmin clone-service --sourceservice name-of-the-source-service[--tenant name-of-the-tenant] [environment name-of-the-environment][--servicetype name-of-the-service-type-to-be-used]name-of-the-target-service

In this command, the “--service-type” argument is an optional argumentused when the target service needs to use a different virtualizationconfiguration and/or different provider types for provider dependencies.When the “--servicetype” is not specified, then the target service wouldbe created using the service type of the source service. When the“--servicetype” is specified, then the validation would be done to makesure that the specified servicetype is a clone/copy of source service'sservice type. If the clone-service is attempted through an arbitraryservice type, then the command would fail.

The backup-service command: The backup-service command can be exposed tothe cloud account administrator in order to take the backup of thesource service. This command would be used when cloning the service fromone domain to another. The command syntax can be illustrated as:

cadmin backup-service [--retrieve true-or-false] [--tenantname-of-the-tenant] --backupfile backup-file-namename-of-the-source-service

The restore-service command: The restore-service command can be exposedto the cloud account administrator in order to restore the service inanother CloudLogic domain. This command would be used when cloning theservice from one domain to another. The command syntax can beillustrated as:

cadmin restore-service --backupfile backup-file-name [--tenantname-of-the-tenant] [environment name-of-the-environment] [--servicetypename-of-the-service-type-to-be-used] name-of-the-target-service

Private Interfaces for Service Cloning

In accordance with an embodiment, the commands and tools used forservice cloning can be sme-based modules, which can provide the baseimplementations for the backup and restore functionality. As anillustrative example, invocation of T2P tools viz., copyConfig.sh,makeMovePlan.sh, pasteConfig.sh would be invoked from a sme-base. Thespecific SMEs need to call the sme-base by supplying the necessaryarguments for invoking those T2P commands.

Example Implementation for Service Cloning

Provided below are illustrative examples of cloning a service within aservice domain and across service domains, in accordance with anembodiment.

Example 1 Cloning a Service within the CloudLogic Domain

cadmin clone-service --sourceservice s1 s1_clone

The above command will create s1_clone which is a copy of s1. Thes1_clone can get created in the same virtualization configuration as s1,and the s1_clone can use the same provider types as s1 for its providerdependencies

Example 2

Cloning a service within the CloudLogic domain using a cloned servicetype. In order for the target service to use a different virtualizationand/or different provider types for various provider dependencies, thePaaS administrator must first clone the service type of the sourceservice, as illustrated below:

// Clone the service type of service s1 (i.e., st1) into st1_clone // Weassume the vc2 exists and is of same virtualization type as // definedin service s1's SDP // The dependency names viz., OPSS_DB_DEPENDENCY andIDM_DEPENDENCY // are as defined in the service s1's SDP and all theprovider types //used already // exist in the system. padminclone-service-type --source st1 virtualization --virtualization vc2--dependency-names OPSS_DB_DEPENDENCY=oracle-db-provider-type: IDMDEPENDENCY=oidprovidertype st1_clone

Once the st1_clone is set up by the PaaS administrator, the cloudaccount administrator(s) can use this st1_clone while cloning theservice that was created from st1. For example:

Cadmin clone-service --sourceservice s1 --servicetype st1_clone s1_clone

The above command will create s1_clone which is a copy of s1. Thes1_clone will use a different virtualization configuration and differentprovider types than s1 as it is configured in service type st1_clone.

Example 3

Clone a service across the CloudLogic domains. In order to clone theservice from one CloudLogic domain to another CloudLogic domain, thecommands need to be executed in both domains. In the source servicedomain, the following commands can be run:

//Export all the virtualization configurations, service types and //allthe SDPs from source service domain. padmin exportdomain<<arguments>>source_domain.zip //Extract the backup from the source service cadminbackup-service --backupfile /tmp/s1_backup.zip s1In the target service domain, the follow commands can be run:

// Import all the virtualization configurations, service types and //allthe SDPs from source service domain. padmin importdomain <<arguments>>source_domain.zip // In the target service domain the names ofvirtualization configurations, // service types and names of the SDPswill remain same as what // it was in source service domain // Downloadthe source service's backup from source service domain into /tmp // Nowcreate a target service and apply the backup cadmin create-service--service-type st1 s1_clone cadmin restore-service --backupfile/tmp/s1_backup.zip s1_clone

The present invention may be conveniently implemented using one or moreconventional general purpose or specialized digital computer, computingdevice, machine, or microprocessor, including one or more processors,memory and/or computer readable storage media programmed according tothe teachings of the present disclosure. Appropriate software coding canreadily be prepared by skilled programmers based on the teachings of thepresent disclosure, as will be apparent to those skilled in the softwareart.

In some embodiments, the present invention includes a computer programproduct which is a non-transitory storage medium or computer readablemedium (media) having instructions stored thereon/in which can be usedto program a computer to perform any of the processes of the presentinvention. The storage medium can include, but is not limited to, anytype of disk including floppy disks, optical discs, DVD, CD-ROMs,microdrive, and magneto-optical disks, ROMs, RAMs, EPROMs, EEPROMs,DRAMs, VRAMs, flash memory devices, magnetic or optical cards,nanosystems (including molecular memory ICs), or any type of media ordevice suitable for storing instructions and/or data.

The foregoing description of the present invention has been provided forthe purposes of illustration and description. It is not intended to beexhaustive or to limit the invention to the precise forms disclosed.Many modifications and variations will be apparent to the practitionerskilled in the art. The embodiments were chosen and described in orderto best explain the principles of the invention and its practicalapplication, thereby enabling others skilled in the art to understandthe invention for various embodiments and with various modificationsthat are suited to the particular use contemplated. It is intended thatthe scope of the invention be defined by the following claims and theirequivalents.

What is claimed is:
 1. A system for replicating configurations from asource service domain to a target service domain in a cloud computingplatform environment, comprising: one or more computers including acloud environment executing thereon; a cloud platform component providedas an installable software suite within the cloud environment, thatsupports provisioning of enterprise applications; and a test toproduction (T2P) framework module that includes a platform as a service(PaaS) plugin and a plurality of T2P plugins; wherein the plurality ofT2P plugins and the PaaS plugin are invoked to replicate a sourceservice domain to a target service domain within the cloud environment.2. The system of claim 1, wherein a domain configuration archive iscreated to contain service domain configurations of the source servicedomain and a move plan for each service domain configuration.
 3. Thesystem of claim 2, wherein the move plan for each service domainconfiguration includes one or more files with customizable parametersfor a service domain.
 4. The system of claim 2, wherein the move planfiles are extracted from the domain configuration archive and customizedat a user interface based on requirements of the target service domain.5. The system of claim 4, wherein the customized move plans are used torecreate the service domain configurations in the target service domain.6. The system of claim 1, wherein the service domain configurationsinclude one or more of a virtualization configuration, a servicedefinition package configuration, a service type configuration, aprovider type configuration, a service resource type configuration, anda tenant structure configuration.
 7. A method of providing functionalityin a cloud computing environment, comprising: providing, at one or morecomputers including a cloud environment executing thereon, a cloudplatform component as an installable software suite that supportsprovisioning of enterprise applications; and providing a test toproduction (T2P) framework module that includes a platform as a service(PaaS) plugin and a plurality of T2P plugins; wherein the plurality ofT2P plugins and the PaaS plugin are invoked to replicate a sourceservice domain to a target service domain within the cloud environment.8. The method of claim 7, wherein a domain configuration archive iscreated to contain service domain configurations of the source servicedomain and a move plan for each service domain configuration.
 9. Themethod of claim 8, wherein the move plan for each service domainconfiguration includes one or more files with customizable parametersfor a service domain.
 10. The method of claim 8, wherein the move planfiles are extracted from the domain configuration archive and customizedat a user interface based on requirements of the target service domain.11. The method of claim 10, wherein the customized move plans are usedto recreate the service domain configurations in the target servicedomain.
 12. The method of claim 7, wherein the service domainconfigurations include one or more of a virtualization configuration, aservice definition package configuration, a service type configuration,a provider type configuration, a service resource type configuration,and a tenant structure configuration.
 13. A non-transitory computerreadable storage medium, including instructions stored thereon whichwhen read and executed by one or more computers cause the one or morecomputers to perform the steps comprising: providing, at one or morecomputers including a cloud environment executing thereon, a cloudplatform component as an installable software suite that supportsprovisioning of enterprise applications; and providing a test toproduction (T2P) framework module that includes a platform as a service(PaaS) plugin and a plurality of T2P plugins; wherein the plurality ofT2P plugins and the PaaS plugin are invoked to replicate a sourceservice domain to a target service domain within the cloud environment.14. The non-transitory computer readable storage medium of claim 13,wherein a domain configuration archive is created to contain servicedomain configurations of the source service domain and a move plan foreach service domain configuration.
 15. The non-transitory computerreadable storage medium of claim 14, wherein the move plan for eachservice domain configuration includes one or more files withcustomizable parameters for a service domain.
 16. The non-transitorycomputer readable storage medium of claim 14, wherein the move planfiles are extracted from the domain configuration archive and customizedat a user interface based on requirements of the target service domain.17. The non-transitory computer readable storage medium of 16, whereinthe customized move plans are used to recreate the service domainconfigurations in the target service domain.
 18. The non-transitorycomputer readable storage medium of claim 13, wherein the service domainconfigurations include one or more of a virtualization configuration, aservice definition package configuration, a service type configuration,a provider type configuration, a service resource type configuration,and a tenant structure configuration.